Power Supply Current Spike Reduction Techniques for an Integrated Circuit

ABSTRACT

An integrated circuit includes a first clock island, a second clock island, a clock generator, and a first programmable delay element. The first clock island is configured to receive a first clock signal. The second clock island is configured to receive a second clock signal. The clock generator is configured to provide a generated clock signal and the first and second clock signals are based on the generated clock signal. The first programmable delay element is coupled between the clock generator and the first clock island. The first programmable delay element is configured to receive the generated clock signal and provide the first clock signal. The integrated circuit is configured to account for a clock skew between the first and second clock signals when information is transferred between the first and second clock islands. In this manner, a predetermined amount of the clock skew may be introduced between the first and second clock signals to smear out, over time, instantaneous power supply current demands of respective logic within the first and second clock islands.

BACKGROUND

1. Field

This disclosure relates generally to an integrated circuit and, morespecifically, to power supply current spike reduction techniques for anintegrated circuit.

2. Related Art

Today, the trend in clock design for relatively large integratedcircuits (chips) has been to implement relatively low clock skew for allclock islands (i.e., logic blocks in different clock domains) of a chip.As clock skew reduces available cycle time, lower clock skew hasgenerally provided better chip performance. Clock skew targets of tenpicoseconds or less are common in clock designs with cycle times oftwo-hundred fifty picoseconds or less. However, achieving clocks skewsof ten picoseconds or less across an entire chip can be relativelychallenging. Moreover, power integrity, power consumption, decouplingcapacitor real estate, packaging cost, back-end-of-line (BEOL) grid(i.e., interconnects and vias) cost, and schedule goals may be difficultto attain in chips that are designed to maintain clock skews of tenpicoseconds or less across an entire chip. For example, maintainingrelatively low clock skew across an entire chip may cause relativelylarge chips to generate relatively large current spikes (e.g., 920amperes/nanosecond), which may lead to relatively large power supplyvoltage droops (e.g., power supply voltage droops of ten to twentypercent). In a known input/output (I/O) design approach, clock skew hasbeen intentionally introduced between I/O buffers associated with an I/Obus in an attempt to reduce interference between adjacent signal paths.

Power supply voltage droop generally causes loss of performance (due toincreased circuit delay) if a power supply voltage is not raised tocompensate for the voltage droop or relatively high power dissipationresults if the power supply voltage is raised to compensate for thevoltage droop. Moreover, power supply overshoot (attributable to packageinductance) can cause reliability and/or functional issues withnoise-susceptible circuitry, such as memory arrays and analog circuits.Known solutions used to mitigate power issues associated with relativelylarge current spikes include dedicating on-chip real estate (typicallyabout ten percent) to thin-oxide decoupling capacitor cells and/oremploying deep-trench capacitors within a chip.

However, on-chip decoupling capacitors are relatively expensive and maylead to decreased integrated circuit yield, due to failure of theon-chip decoupling capacitors. Moreover, even near-ideal on-die powersupply decoupling may not satisfy all current spikes, which can exceedone-hundred forty amperes. Additionally, addressing current spikesattributable to reduced clock skew generally also increases first-leveland second-level packaging costs. For example, exotic packages (e.g.,glass on ceramic) and discrete surface mount technology (SMT) capacitorsmay be employed to mitigate current spikes. Unfortunately, exoticpackages are relatively expensive and discrete SMT capacitors tend to becumbersome to install. For example, locating package decouplingcapacitors close to a chip (e.g., underneath a die) has led to moreexpensive designs in which one or more holes have been provided in anassociated printed circuit board (or card). While high-frequencylow-inductance chip array (LICA) capacitors may be implemented off-chipto address current spikes, implementing LICA capacitors off-chip isrelatively expensive and may be cost prohibitive for many designs.

SUMMARY

According to one aspect of the present disclosure, an integrated circuitincludes a first clock island, a second clock island, a clock generator,and a first programmable delay element. The first clock island isconfigured to receive a first clock signal. The second clock island isconfigured to receive a second clock signal. The clock generator isconfigured to provide a generated clock signal and the first and secondclock signals are based on the generated clock signal. The firstprogrammable delay element is coupled between the clock generator andthe first clock island. The first programmable delay element isconfigured to receive the generated clock signal and provide the firstclock signal. The integrated circuit is also configured to account for aclock skew between the first and second clock signals when informationis transferred between the first and second clock islands. According tovarious aspects of the present disclosure, a predetermined amount of theclock skew is introduced to smear out (over time) instantaneous powersupply current demands of respective logic within the first and secondclock islands. In this manner, composite (global) chip-level currentdemands may be smoothed out to effectively reduce power supply noise.

According to another aspect of the present disclosure, a technique forincreasing integrated circuit yield includes providing a first clocksignal to a first clock island included in an integrated circuit. Asecond clock signal is provided to a second clock island included in theintegrated circuit. The first and second clock signals are based on agenerated clock signal. A first clock skew of the first clock signal isadjusted. A first value for the first clock skew is determined whensignals passing between the first and second clock islands both passtiming requirements. The first value is then programmed into a firstprogrammable delay element that is coupled between a clock generator(that provides the generated clock signal) and the first clock island.

According to one embodiment of the present disclosure, an integratedcircuit includes a first clock island, a second clock island, a clockgenerator, and a first programmable delay element. The first clockisland is configured to receive a first clock signal. The second clockisland is configured to receive a second clock signal. The first clockisland includes a first logic block (e.g., a first processor core) andthe second clock island includes a second logic block (e.g., a secondprocessor core). The clock generator is configured to provide agenerated clock signal and the first and second clock signals are basedon the generated clock signal. The first programmable delay element iscoupled between the clock generator and the first clock island. Thefirst programmable delay element is configured to receive the generatedclock signal and provide the first clock signal. The integrated circuitis also configured to account for a clock skew between the first andsecond clock signals when information is transferred between the firstand second clock islands.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention is illustrated by way of example and is notintended to be limited by the accompanying figures, in which likereferences indicate similar elements. Elements in the figures areillustrated for simplicity and clarity and have not necessarily beendrawn to scale.

FIG. 1 is a diagram of an integrated circuit (chip) that includesmultiple clock islands that are clocked by a common clock signal that isskewed (by, for example, a different amount for each of the clockislands) to reduce current spikes, according to the present disclosure.

FIG. 2 depicts example current-demand waveforms that illustrate asmoothing affect in instantaneous current draw achieved by the chip ofFIG. 1.

FIG. 3 is a diagram of a chip that includes multiple clock islands thatare clocked by a common clock signal that is skewed (by a differentamount for each of the clock islands) to reduce current spikes andincludes delay elements that are employed to facilitate properly timedinformation transfer between the clock islands, according to oneembodiment of the present disclosure.

FIG. 4 is a diagram of a chip that includes multiple clock islands thatare clocked by a common clock signal that is skewed (by a differentamount for each of the clock islands) to reduce current spikes andincludes delay elements that are employed to facilitate properly timedinformation transfer between the clock islands, according to anotherembodiment of the present disclosure.

FIG. 5 is a diagram of a chip that includes multiple clock islands thatare clocked by a common clock signal that is skewed (by a differentamount for each of the clock islands) to reduce current spikes andincludes delay elements that are employed to facilitate properly timedinformation transfer between the clock islands, according to yet anotherembodiment of the present disclosure.

FIG. 6 is a diagram of a chip that includes multiple clock islands thatare clocked by a common clock signal that is skewed (by a differentamount for each of the clock islands) to reduce current spikes andincludes delay elements that are employed to facilitate properly timedinformation transfer between the clock islands, according to anotherembodiment of the present disclosure.

FIG. 7 is a flowchart of an example process for increasing integratedcircuit yield according to one embodiment of the present disclosure.

FIG. 8 is a block diagram of an example computer system that may employone or more chips that implement clock skewing to reduce current spikesaccording to the present disclosure.

DETAILED DESCRIPTION

As will be appreciated by one of ordinary skill in the art, the presentinvention may be embodied as a method, system, device, or computerprogram product. Accordingly, aspects of the present invention may takethe form of an entirely hardware embodiment, an entirely softwareembodiment, or an embodiment combining software and hardware aspectsthat may all generally be referred to herein as a “circuit,” “module,”or “system.” For example, an entirely software embodiment of the presentinvention may take the form of one or more design files encoded on acomputer-usable storage medium.

Any suitable computer-usable or computer-readable storage medium may beutilized. The computer-usable or computer-readable storage medium maybe, for example, but is not limited to an electronic, magnetic, optical,electromagnetic, infrared, or semiconductor system, apparatus, ordevice. More specific examples (a non-exhaustive list) of thecomputer-readable medium includes the following: a portable computerdiskette, a hard disk, a random access memory (RAM), a read-only memory(ROM), an erasable programmable read-only memory (EPROM) or Flashmemory, a portable compact disc read-only memory (CD-ROM), an opticalstorage device, or a magnetic storage device. Note that thecomputer-usable or computer-readable storage medium could even be paperor another suitable medium upon which the program is printed, as theprogram can be electronically captured, via, for instance, opticalscanning of the paper or other medium, then compiled, interpreted, orotherwise processed in a suitable manner, if necessary, and then storedin a computer memory. In the context of this disclosure, acomputer-usable or computer-readable storage medium may be any mediumthat can contain or store a program for use by or in connection with aninstruction execution system, apparatus, or device. As used herein, theterm “coupled” includes both a direct electrical connection betweenblocks or components and an indirect electrical connection betweenblocks or components achieved using intervening blocks or components.

As noted above, conventionally, relatively low clock skew designs havebeen implemented to improve global timing for an integrated circuit(chip). Moreover, in a typical application, local clock skew within agiven clock island is maintained at a relatively low level to simplifylocal timing. However, relatively low clock skew designs may lead tolarger power supply current spikes over shorter time periods, which canincrease instantaneous power consumption and increase packaging costsfor a chip. The present disclosure is generally directed to techniques(that also tend to reduce a cost of the chip) for reducing global powersupply current spikes and instantaneous power consumption of a chip.Normally, reducing global power supply spikes reduces overall chip powerconsumption. According to the present disclosure, power supply spikesare generally reduced by isolating clock islands and performing globalskew engineering. It should be appreciated that when clock signalsprovided to different clock islands of a chip are skewed with respect toeach other the introduced skew must also be considered when transferringinformation between the clock islands. As used herein, the term “clockisland” is used to denote a logic block that, within a specific clockdomain, is triggered off the same clock signal. According to variousaspects of the present disclosure, instantaneous global power demand ofa chip is reduced by introducing a controlled amount of clock skewbetween clock islands across a chip. In various embodiments, the clockislands follow natural logic partitions dictated by a designarchitecture. For example, each of the clock islands may correspond to adifferent central processing unit (CPU) core of an integrated circuitthat includes multiple CPU cores.

According to the present disclosure, an engineered amount of clock skewis introduced between clock islands, while communication between theclock islands is engineered to provide a finite clock skew between theclock islands. In this manner, global power demand is averaged out (inspace and time) to reduce overall power consumption and simplify powerdelivery. Various disclosed techniques reverse the current design trend(of reducing clock skew to a minimum amount) by intentionallyintroducing an engineered amount of clock skew between clock islands ofa chip to effectively smooth out overall (global) current demand of thechip. Engineering the propagation delay of clock signal fan- out paths(provided to respective clock islands of a chip) to have different clockskews generally reduces (local and global) voltage droop at the chip,while improving performance and reliability of the chip. Hardwarefeatures (e.g., fixed buffers or programmable delay lines) provided on achip may be employed to facilitate adjustment of clock edges on clocksignals provided by a single clock generator to various clock islands(clock domains). Clock edges can be adjusted statically (e.g., set oncein hardware) or dynamically (adjusted in real- time (based on currentconditions) or periodically). In various embodiments, signals spanningclock domains are architected and timed to ensure no late mode or earlymode violations are generated when clock edges are moved.

With reference to FIG. 1, an example chip 100 includes four clockislands 102, 104, 106, and 108 that each receive respective clocksignals from a single clock generator 110. As is illustrated: the island102 receives a first clock signal from the clock generator 110 that isnot skewed; the island 104 receives a second clock signal from the clockgenerator 110 that is skewed by, for example, an amount approximatelyequal to one-quarter of a clock cycle; the island 106 receives a thirdclock signal from the clock generator 110 that is skewed by, forexample, one-half of the clock cycle; and the island 108 receives afourth clock signal from the clock generator 110 that is skewed by, forexample, three-quarters of the clock cycle. The clock skews for theislands 104, 106, and 108 are provided by delay elements 112, 114, and116, respectively. The delay elements 112-116 may be, for example,programmable delay elements or fixed delay elements (such as buffers).Turning to FIG. 2, a diagram 200 illustrates respective instantaneous(local) power supply current demand waveforms (labeled ‘A’, ‘B’, ‘C’,and ‘D’, respectively) for each of the islands 102-108, as well as anoverall (global) instantaneous current (labeled ‘A+B+C+D) for the chip100. It should be noted that by intentionally engineering the clock skewto each of the clock islands 102-108 an overall global power supplydemand is smoothed out over time. It should be appreciated that thetechniques disclosed herein are broadly applicable to chips that havetwo or more skew-engineered clock islands.

Moving to FIG. 3, a chip 300 includes four clock islands 302, 304, 306,and 308 that each receive respective clock signals from a single clockgenerator 310. As is illustrated: the island 302 receives a first clocksignal from the clock generator 310 that is not skewed; the island 304receives a second clock signal from the clock generator 310 that isskewed by one-quarter of a clock cycle; the island 306 receives a thirdclock signal from the clock generator 310 that is skewed by one-half ofthe clock cycle; and the island 308 receives a fourth clock signal fromthe clock generator 310 that is skewed by three-quarters of the clockcycle. The clock skew for the islands 304, 306, and 308 are provided bydelay elements 312, 314, and 316, respectively. As is also illustrated,delay elements 320, 322, and 324, are provided for transferring databetween the islands 302 and 304, the islands 304 and 306, and theislands 306 and 308, respectively. As is illustrated, each of the delayelements 320-324 introduce a (similar) one-quarter clock cycle delay. Invarious embodiments, the delay elements 312-324 are either programmabledelay elements or fixed delay elements.

With reference to FIG. 4, a chip 400 includes four clock islands 402,404, 406, and 408 that each receive respective clock signals from asingle clock generator 410. As is illustrated: the island 402 receives afirst clock signal that is not skewed; the island 404 receives a secondclock signal that is skewed by one-quarter of a clock cycle; the island406 receives a third clock signal that is skewed by one-half of theclock cycle; and the island 408 receives a fourth clock signal that isskewed by three-quarters of the clock cycle. The clock skew for theislands 404, 406, and 408 are provided by delay elements 412, 414, and416, respectively. As is also illustrated, delay elements 420, 422, 424,and 426, are provided for transferring data between the islands 402 and404, the islands 404 and 406, the islands 406 and 408, and the islands402 and 406, respectively. The delay elements 412-426 may be fixed orprogrammable delay elements depending upon the embodiment.

With reference to FIG. 5, a chip 500 includes four clock islands 502,504, 506, and 508 that each receive respective clock signals. As isillustrated: the island 502 receives a first clock signal from clockgenerator 510 that is not skewed; the island 504 receives a second clocksignal from the clock generator 510 that is skewed by one-quarter of aclock cycle; the island 506 receives a third clock signal from the clockgenerator 510 that is skewed by one-half of the clock cycle; and theisland 508 receives a fourth clock signal from the clock generator 510that is skewed by three-quarters of the clock cycle. The clock skew forthe islands 504, 506, and 508 are provided by delay elements 512, 514,and 516, respectively. As is also illustrated, delay elements 520, 522,524, 526, and 528, are provided for transferring data between theislands 502 and 504, the islands 504 and 506, the islands 506 and 508,the islands 502 and 506, and the islands 502 and 508 respectively. Thedelay elements 512-528 may be programmable or fixed delay elements,depending on the embodiment.

With reference to FIG. 6, a chip 600 includes four clock islands 602,604, 606, and 608 that each receive respective clock signals from asingle clock generator 610. As is illustrated: the island 602 receives afirst clock signal that is not skewed; the island 604 receives a secondclock signal that is skewed by one-quarter of a clock cycle; the island606 receives a third clock signal that is skewed by one-half of theclock cycle; and the island 608 receives a fourth clock signal that isskewed by three-quarters of a clock cycle. The clock skew for theislands 604, 606, and 608 are provided by delay elements 612, 614, and616, respectively. As is also illustrated, delay elements 620, 622, 624,626, 628 and 630, are provided for transferring data between the islands602 and 604, the islands 604 and 606, the islands 606 and 608, theislands 602 and 606, the islands 602 and 608, and the islands 608 and602, respectively. The delay elements 612-630 may be programmable orfixed delay elements. It should be appreciated that cycle stealing maybe employed to transfer information between clock islands to ease timingrequirements. For example, the delay element 630 may be implemented tointroduce a delay of one-quarter clock cycle to a signal that islaunched in a previous clock cycle to effect data transfer between theislands 608 and 602. Engineering the generation of a given signal toappear one cycle early (generally described as cycle stealing) is usefulin timing situations where transmitting a signal from islands 608 to 602in one-quarter cycle, for example, may not be practical or convenient.

As should be obvious to one skilled in the art upon reading thisdisclosure, the actual amount of skew implemented between each of theislands may not be exactly one quarter of a clock cycle, or the sum ofskews may not necessarily add up to nearly an entire clock cycle. Ingeneral, selected clock skews are an engineered trade-off between powersupply spike reduction and practical timing closure (especially withrespect to timing between the island 608 and the island 602).

With reference to FIG. 7, an example process 700 for increasing yield ofan integrated circuit (chip) is illustrated. The process 700 attempts todetermine a clock skew or clock skews that allow the chip to pass timingrequirements for signal passing between the various clock islandimplemented within a chip. In block 702, the process 700 is initiated atwhich point control transfers to block 704. In block 704, clock signalsare provided to each of the clock islands according to an initial clockskew arrangement. Next, in block 706, one or more of the clock skews(according to an implemented technique) is adjusted. Then, in block 708,it is determined whether the chip passes timing requirements. Next, inblock 710, one or more values are programmed into one or more registersof one or more programmable delay elements (that provide the clockskew(s)). Following block 710, control transfers to block 712, where theprocess 700 terminates and returns to a calling routine.

With reference to FIG. 8, an example computer system 800 is illustratedthat may include one or more circuits that employ chips configuredaccording to various embodiments of the present disclosure. The computersystem 800 includes a processor 802 that is coupled to a memorysubsystem 804, a display 806, and an input device 808. The processor 802(or other chips) may include one or more clock islands whose clock skewsare configured according to the present disclosure. The memory subsystem804 includes an application appropriate amount of volatile memory (e.g.,dynamic random access memory (DRAM)) and non-volatile memory (e.g.,read-only memory (ROM)). The display 806 (which may be local or remote)may be, for example, a cathode ray tube (CRT) or a liquid crystaldisplay (LCD). The input device 808 may include, for example, a mouseand a keyboard. The processor 802 may also be coupled to one or moremass storage devices, e.g., a compact disc read-only memory (CD-ROM)drive.

Accordingly, techniques have been disclosed herein that readilyfacilitate the reduction of current spikes in an integrated circuit thatincludes two or more clock islands whose clock signals are skewed withrespect to each other.

The flowchart and block diagrams in the figures illustrate thearchitecture, functionality, and operation of possible implementationsof systems, methods and computer program products according to variousembodiments of the present invention. In this regard, each block in theflowchart or block diagrams may represent a module, segment, or portionof code, which comprises one or more executable instructions forimplementing the specified logical function(s). It should also be notedthat, in some alternative implementations, the functions noted in theblock may occur out of the order noted in the figures. For example, twoblocks shown in succession may, in fact, be executed substantiallyconcurrently, or the blocks may sometimes be executed in the reverseorder, depending upon the functionality involved. It will also be notedthat each block of the block diagrams and/or flowchart illustration, andcombinations of blocks in the block diagrams and/or flowchartillustration, can be implemented by special purpose hardware-basedsystems that perform the specified functions or acts, or combinations ofspecial purpose hardware and computer instructions.

The terminology used herein is for the purpose of describing particularembodiments only and is not intended to be limiting of the invention. Asused herein, the singular forms “a”, “an” and “the” are intended toinclude the plural forms as well, unless the context clearly indicatesotherwise. It will be further understood that the terms “comprises,”and/or “comprising,” when used in this specification, specify thepresence of stated features, integers, steps, operations, elements,and/or components, but do not preclude the presence or addition of oneor more other features, integers, steps, operations, elements,components, and/or groups thereof.

The corresponding structures, materials, acts, and equivalents of allmeans or step plus function elements in the claims below, if any, areintended to include any structure, material, or act for performing thefunction in combination with other claimed elements as specificallyclaimed. The description of the present invention has been presented forpurposes of illustration and description, but is not intended to beexhaustive or limited to the invention in the form disclosed. Manymodifications and variations will be apparent to those of ordinary skillin the art without departing from the scope and spirit of the invention.The embodiment was chosen and described in order to best explain theprinciples of the invention and the practical application, and to enableothers of ordinary skill in the art to understand the invention forvarious embodiments with various modifications as are suited to theparticular use contemplated.

Having thus described the invention of the present application in detailand by reference to preferred embodiments thereof, it will be apparentthat modifications and variations are possible without departing fromthe scope of the invention defined in the appended claims.

1. An integrated circuit, comprising: a first clock island configured toreceive a first clock signal; a second clock island configured toreceive a second clock signal; a clock generator configured to provide agenerated clock signal, wherein the first and second clock signals arebased on the generated clock signal; and a first programmable delayelement coupled between the clock generator and the first clock island,wherein the first programmable delay element is configured to receivethe generated clock signal and provide the first clock signal, andwherein the integrated circuit is configured to account for a clock skewbetween the first and second clock signals when information istransferred between the first and second clock islands.
 2. Theintegrated circuit of claim 1, further comprising: a second programmabledelay element coupled between the clock generator and the second clockisland, wherein the second programmable delay element is configured toreceive the generated clock signal and provide the second clock signal.3. The integrated circuit of claim 1, wherein the second clock signalcorresponds to the generated clock signal.
 4. The integrated circuit ofclaim 1, wherein the first clock island includes a first centralprocessing unit core.
 5. The integrated circuit of claim 4, where thesecond clock island includes a second central processing unit core. 6.The integrated circuit of claim 1, wherein a time delay provided by thefirst delay element is less than one cycle of the generated clocksignal.
 7. The integrated circuit of claim 1, wherein a predeterminedamount of the clock skew is introduced between the first and secondclock signals to smear out, over time, instantaneous power supplycurrent demands of respective logic within the first and second clockislands.
 8. A method of increasing integrated circuit yield, comprising:providing a first clock signal to a first clock island included in anintegrated circuit; providing a second clock signal to a second clockisland included in the integrated circuit, wherein the first and secondclock signals are based on a generated clock signal; adjusting a firstclock skew of the first clock signal; determining a first value for thefirst clock skew when signal paths between the first and second clockislands each pass timing requirements; and programming the first valueinto a first programmable delay element that is coupled between a clockgenerator and the first clock island.
 9. The method of claim 8, furthercomprising: adjusting a second clock skew of the second clock signal;determining a second value for the second clock skew when the signalpaths between the first and second clock islands each pass the timingrequirements; and programming the second value into a secondprogrammable delay element that is coupled between a clock generator andthe second clock island.
 10. The method of claim 8, wherein the firstclock signal is a time-delayed version of the second clock signal andthe method further comprises: transmitting data from the second clockisland to the first clock island in a same cycle of the generated clocksignal.
 11. The method of claim 8, further comprising: transmitting datafrom the first clock island to the second clock island using cyclestealing.
 12. The method of claim 8, further comprising: adjusting thefirst value based on an instantaneous power consumption profile of theintegrated circuit.
 13. The method of claim 8, further comprising:adjusting the first value to reduce electro-migration in a powerdistribution grid of the integrated circuit.
 14. An integrated circuit,comprising: a first clock island configured to receive a first clocksignal, wherein the first clock island includes a first logic block; asecond clock island configured to receive a second clock signal, whereinthe second clock island includes a second logic block; a clock generatorconfigured to provide a generated clock signal, wherein the first andsecond clock signals are based on the generated clock signal; and afirst programmable delay element coupled between the clock generator andthe first clock island, wherein the first programmable delay element isconfigured to receive the generated clock signal and provide the firstclock signal, and wherein the integrated circuit is configured toaccount for a clock skew between the first and second clock signals wheninformation is transferred between the first and second clock islands.15. The integrated circuit of claim 14, further comprising: a secondprogrammable delay element coupled between the clock generator and thesecond clock island, wherein the second programmable delay element isconfigured to receive the generated clock signal and provide the secondclock signal.
 16. The integrated circuit of claim 15, furthercomprising: a third programmable delay element coupled between thesecond clock island and the first clock island, wherein the thirdprogrammable delay element is configured to delay data generated by thesecond clock island that is transmitted to the first clock island. 17.The integrated circuit of claim 16, further comprising: a fourthprogrammable delay element coupled between the first clock island andthe second clock island, wherein the fourth programmable delay elementis configured to delay data generated by the first clock island that istransmitted to the second clock island.
 18. The integrated circuit ofclaim 14, wherein the second clock signal corresponds to the generatedclock signal.
 19. The integrated circuit of claim 14, wherein a timedelay provided by the first delay element is less than one cycle of thegenerated clock signal.
 20. The integrated circuit of claim 14, whereina predetermined amount of the clock skew is introduced between the firstand second clock signals to smear out, over time, instantaneous powersupply current demands of respective logic within the first and secondclock islands, and wherein the clock skew effectively reduces powersupply noise.